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US2775632A - Treatment of aromatic hydrocarbons - Google Patents

Treatment of aromatic hydrocarbons Download PDF

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US2775632A
US2775632A US354742A US35474253A US2775632A US 2775632 A US2775632 A US 2775632A US 354742 A US354742 A US 354742A US 35474253 A US35474253 A US 35474253A US 2775632 A US2775632 A US 2775632A
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aromatic
clay
yield
water
water content
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Earl M Honeycutt
James R Calkins
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Sunoco Inc
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Sun Oil Co
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    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07CACYCLIC OR CARBOCYCLIC COMPOUNDS
    • C07C15/00Cyclic hydrocarbons containing only six-membered aromatic rings as cyclic parts
    • C07C15/02Monocyclic hydrocarbons
    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10GCRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
    • C10G21/00Refining of hydrocarbon oils, in the absence of hydrogen, by extraction with selective solvents
    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10GCRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
    • C10G25/00Refining of hydrocarbon oils in the absence of hydrogen, with solid sorbents
    • C10G25/02Refining of hydrocarbon oils in the absence of hydrogen, with solid sorbents with ion-exchange material

Definitions

  • Swarthmore Pa'.,. assignors to. Sun .Oil Company, Philadelphia; Pa., a corporation or New Jersey Application Mayi13,n1 953,1Serial No. 354,742
  • Aromatics such asbenzene, toluene, .Xylenes, etc. have been produced from petroleum byvarious procedures including thermal and catalytic reaction steps in combination with suitable procedures for separating and concentrating the aromatic. from non-aromatic products.
  • a pro .cedure now used extensively comprises vreforming .of petroleum naphthas to convert non-aromatic to .aromatic hydrocarbons, followed by selective extraction of the aromaticsby means of a suitable solvent'suchas diethylene glycol.
  • clay heretofore used for :this purpose has been the usual commercial material, which has a combined moisture content generally of about by weight.
  • the present invention isdirected to wan-improvement in the clay treatment of aromatic stocks for the purpose of improving the acid wash color. It has now been found that in treating the aromatic stock in liquid phase with clay at elevated temperature, a very substantial increase in the-yield of product meeting'nitration grade specifications perton of clay can be effected by.using clay which :has' a combined water content within the range of 45-75% by weight. For example, when ordinarycommercial clay having about 10% combined water is .employed, typical yields of nitration grade product are 1000-1500 bbls./ ton of clay; whereas when the combined water content is reduced towithin the range specified, yields of the order of 3500bbls./ton of clay are obtainable. p
  • the invention thus comprises treating an aromatic stock, which initially possesses unsatisfactory acid wash '.'c0l0 1,-in liquid phase and at sufiiciently. elevated temperat-ture with; adsorptive -clay havingwa combined water content within therange of 4.5-7.5 by weight.
  • the tem- United States Patent Q perature should be above' 275:--F.-1but below the critical temperature of the aromatic :stoc'k,candgspreferably' is maintained'withinthe range of 300'375.F. :iSufiicient pressure :is used to keep the :aromatic Fcharge in liquid .phase.
  • Contact of the aromaticstock with thezclay rat by distillation. -Ayield of .nitratiomgrade productiin excess of 2000 bbls.'/ton of clay 'can-readily .:be'.obtained in this manner.
  • naphtha isfed to 'a reformingstep v10 wherein conditions step ,may comprise any .known .orsuitable reforming procedures.
  • Reaction product from the reforming-step 10 is composed of the desired aromatic hydrocarbon in admixture with hydrocarbons from which the de'siredaromatic must be separated by a suitable concentrating procedure.”
  • suitable concentrating procedure may include distillation and/orextraction, and
  • extraction step 11 This step may comprise extraction of the reformate'product, or a fraction thereof obtainedby distillation, with a suitable solvent selective for the aromatic component, for example, with diethylene glycol containing a minor amount of water.
  • a suitable solvent selective for the aromatic component for example, with diethylene glycol containing a minor amount of water.
  • the aromatic :extract .is..recovered from the solvent by distillation andv is normally water washed to remove traces of solvent. .
  • Thisresults .in an aromatic fraction which is relatively wettdue to the :fact that the solubilityof water in..aromatic:hydrocarbons is substantial.
  • The. wetaromatic fraction obtained. from stepll must be subjected .to a drying step 12 beforetreatment-with clay in accordance with the present invention.
  • a drying step 12 Any known or suitable dryingprccedure capable of reducing the water content below 200 p. p. m. maybe used for this purpose.
  • the next step, illustrated in the drawing by numeral 13 is the treating step in which the dried aromatic stock in liquid form is brought into contact at elevated temperature with adsorptive clay having a combined water content of 4i5-7.5%.
  • the clay can be prepared by roasting conventional commercial clay of higher moisture content at a temperature of, for example, about 1000 F. until the combined water content is reduced to within the desired range of 4.5-7.5% and preferably to 5.86.5%.
  • the specified range of cornbined water content of the clay is critical for obtaining the desired improvement according to the invention.
  • the temperature of treatment in step 13 should be above 275 F., preferably 300-375 F., with the prestually the clay will lose its activity, probably due to accumulation of polymers therein, and will have to be replaced by fresh clay or regenerated before further use.
  • the high yield of product obtained according to the invention will minimize the cost of replacement or regeneration of the clay.
  • the efiluent from the clay treating step 13 generally has an acid wash color substantially improved over that of the aromatic charge but contains some polymeric materials which preferably should be removed to improve acid wash color still further. This may be done 'by means of distillation step 14. In this step the treated aromatic is distilled overhead leaving the undesirable polymeric material as residuum.
  • the yield of distillate meeting nitration grade specifications will be in excess of 2000 bbls. per ton of the clay used in step 13 and yields of the order of 30003500 bbls./ton can readily be obtained.
  • the acid wash color of the distillate product will remain more or less constant at a satisfactorily low value until a certain yield in excess of 2000 bbls./ton is reached, after which the acid wash color will sharply increase to an unsatisfactorily high value.
  • the clay should be replaced with fresh or regenerated clay of the proper water content.
  • Example I A commercial clay, designated as 30/60 mesh Attapulgus Grade AA and which had been roasted to a free water content of 0.4% and a combined water content of 10.1%, was used for treating a stock .of petroleum benzene obtained from a reforming operation.
  • the charge stock contained about 98% benzene and met nitration grade specifications except for the acid wash color which was 4. Nitration grade, specifications require an acid wash color not darker than No. 2 color standard and it is desirable that such color be not great-
  • the charge was first dried by filtration through silica gel and then was filtered under pressure and at a temperature of about 300 F. through a'column packed with the clay. A space rate of 5.8 liquid volumes per bulk volume of clay per hour was maintained.
  • Example II Another batch of the benzene specified in Example I and dried by means of silica gel was treated in essentially the same manner with the same type of clay as in that example, but in this case the clay had been roasted until it contained 6.1% combined water and no free water.
  • the acidwash colors for the filtrate before and after distillation were 1 and 0+, respectively; and at a yield of 3000 bbls./ton the colors had increased only slightly to about 1+ and l,
  • Nitration grade specifications were met until a yield of about 3500 bbls./ton was reached, at which time the colors for both the undistilled and distilled product increased sharply to about 3.
  • Example 111 Another run was made as in the preceding example, but in this case the clay had been roasted to a combined water content of 4.0% and no free water. It was found that the yield of nitration grade product was zero. Even the initial filtrate after distillation had about the same acid wash color as the charge benzene. This illustrates the importance of maintaining the combined water content of the clay within the specified range.
  • Example IV The aromatic stock in this case was another commercial benzene prepared by reforming a petroleum naphtha, extracting the reformate with diethylene glycol and water washing.
  • the stock contained of the order of 800 p. p. m. ofwater and had an acid wash color of 12.
  • One portion of the stock was clay treated without drying, while another portion was first subjected to a drying step by distilling 5 vol. overhead so that its water content was reduced to 162 p. p. to.
  • Each portion was filtered as a liquid at 300 F. and at a space rate of 1.0 through 30/60 AA Attapulgus clay which had been roasted to a combined water content of 6.0% and no free water. .
  • Example V A blend composed of, by volume, 47.5% reformer benzene having an acid wash color of 4, 47.5% reformer toluene having an acid wash color of 5+ and 5% n-butane was used as the aromatic charge stock. its water content was less than p. p. m.
  • the clay used was 30/60 AA Attapulgus having no free water and a combined water content of 6.0%.
  • Treatment of the charge stock was effected at a temperature of 300 15., a pressure of 300 p. s. i. g. and a space rate varying from 3.4 to 5.8.
  • the eflluent from the clay treater was stripped of butane and distilled to obtain a polymerfree mixture of benzene and toluene.
  • the mixed benzene and toluene product had an acid wash color less than 1.
  • nitration grade aromatic hydrocarbon which comprises reforming a petroleum naphtha, extracting the reformate with a water soluble solvent to yield an aromatic rich hydrocarbon fraction containing a minor amount of said solvent, and water washing said aromatic rich fraction to remove said solvent, the steps whichcomprise removing water from the water washed aromatic fraction to yield an aromatic stock having a water content less than 200 p. p. m., treating said stock in liquid phase at a temperature between 275 F. and its critical temperature with adsorptive clay having a combined water content between 4.5% and 7.5% by weight, and recovering from the treated material nitration grade aromatic'product in a yield exceeding 2000 barrels per ton of clay.
  • nitration grade aromatic hydrocarbon which comprises reforming a petroleum naphtha and extracting the reformate in the presence 1 of water

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  • Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • General Chemical & Material Sciences (AREA)
  • Production Of Liquid Hydrocarbon Mixture For Refining Petroleum (AREA)
  • Organic Low-Molecular-Weight Compounds And Preparation Thereof (AREA)

Description

Dec. 25, 1956 E. M. HONEYCUTT ETAI. 2,775,632
TREATMENT OF AROMATIC HYDROCARBONS Filed May 15, 1953 Petroleum Nmihtho REFORMING EXTRACTION SoturoIe Fraction Arom0tic Fraction (Wet) DRYING (8 .9. BY DISTILLATION) Wet Distillate Aromufic Fraction CLAY TREATING TEMRI 300- 375F. PREFERRED SUFFICIENT TO MAINTAIN LIQUID PHASE COMBINED WATER IN CLAYZ4.5-7.5%
PRES. 2
- Residuum DISTILLATION (Polymer) NiIrction Grade Aromatic Product (Yield: 2 000 BBLs/ Ton of Clay) INVENTORS. EARL M. HONEYGUTT By JAMES R. CALKINS QM. I am ATTOR EY 2,715,632 TREATMEN-TOEAROMATICIHYDROCARBONS M. Honeycntt, .Claymont, Del and James R. Calirhrs,
Swarthmore, =Pa'.,. assignors to. Sun .Oil Company, Philadelphia; Pa., a corporation or New Jersey Application Mayi13,n1 953,1Serial No. 354,742
-4 Claims. "(CL 260- 674) I This invention relates to the purification of aromatic hydrocarbons and more particularly to the preparation of nitration grade aromatic products. Theinvention is especiallyconcerned with the .manufacture of products of nitration grade from aromatic stocks derived from petroleumand which fail to..conform to nitration .grade specificationsdue to .poor acid wash color.
--Aromatics:such asbenzene, toluene, .Xylenes, etc. have been produced from petroleum byvarious procedures including thermal and catalytic reaction steps in combination with suitable procedures for separating and concentrating the aromatic. from non-aromatic products. A pro .cedure now used extensively comprises vreforming .of petroleum naphthas to convert non-aromatic to .aromatic hydrocarbons, followed by selective extraction of the aromaticsby means of a suitable solvent'suchas diethylene glycol.
Aromatics produced lfrom :petroleum by procedures involving a thermal or catal-ytic reaction generally. fail to meet nitration grade specifications even though the V aromatics have been concentrated to a high state of purity under such trade names as 'Attapulgus clay, Floridin, Mil- -white andnFiltrol, hasbeen employed. Contact of the hot aromaticwstock with clay causes the olefinic constituents to polymerize, andthe polymers can then be separated from, the treated aromatic by distillation. The
clay heretofore used for :this purpose has been the usual commercial material, which has a combined moisture content generally of about by weight.
The present inventionisdirected to wan-improvement in the clay treatment of aromatic stocks for the purpose of improving the acid wash color. It has now been found that in treating the aromatic stock in liquid phase with clay at elevated temperature, a very substantial increase in the-yield of product meeting'nitration grade specifications perton of clay can be effected by.using clay which :has' a combined water content within the range of 45-75% by weight. For example, when ordinarycommercial clay having about 10% combined water is .employed, typical yields of nitration grade product are 1000-1500 bbls./ ton of clay; whereas when the combined water content is reduced towithin the range specified, yields of the order of 3500bbls./ton of clay are obtainable. p
The invention thus comprises treating an aromatic stock, which initially possesses unsatisfactory acid wash '.'c0l0 1,-in liquid phase and at sufiiciently. elevated temperat-ture with; adsorptive -clay havingwa combined water content within therange of 4.5-7.5 by weight. The tem- United States Patent Q perature should be above' 275:--F.-1but below the critical temperature of the aromatic :stoc'k,candgspreferably' is maintained'withinthe range of 300'375.F. :iSufiicient pressure :is used to keep the :aromatic Fcharge in liquid .phase. Contact of the aromaticstock with thezclay rat by distillation. -Ayield of .nitratiomgrade productiin excess of 2000 bbls.'/ton of clay 'can-readily=.:be'.obtained in this manner.
For practice of theinventionito obtainYthe-best yield of nitration grade product, other-factorswhich are-timportant-are the freewater content of'the clay, asdistinguishedi'from' its combined water. content -and the"water content of the aromatic stock. .Theclay when-initially contacted with the stock shouldhaveadow free water content, e. 'g. less than 0.5%byvweight, and/preferably should contain essentially no .free water. The presence offree water tends to-reduce-the. eflfectiveness 'of theclay tin polymerizing the undesirable olefinicnconstituents.tof
the charge. :It has also been found. thatthe waterrcontent of .thearomatic stock tobe treatedsshould-bebelow .200
p. p..m..and preferably should beas lowzas-is practical,
since-the presence of water invthechargetends toieause accumulation of-free .water inutheaclay under. thecon- :tliiiOIlS of pressure and temperature employed in the operation. Aromatic stocks preparedby the widelyused procedure ,involving reforming, extraction .with 1 diethylene glycol and water washing .will rcontain an excessive amount of water (e. g. ,about800 p. "p. m.) .due'tto the high solubility of .watenin aromatic .hydrocarbons; and
such stocks therefore .require Idehydrationf before treatment with clayv in. accordance with .thepresent invention.
The accompanying drawing, which is a schematic illustration of anembodimentrof the..invention,shows the several steps; employed in preparing .nitration grade varomatic product from .a,petroleum..naphtha stock. .The
naphtha isfed to 'a reformingstep v10 wherein conditions step ,may comprise any .known .orsuitable reforming procedures.
Reaction product from the reforming-step 10,is composed of the desired aromatic hydrocarbon in admixture with hydrocarbons from which the de'siredaromatic must be separated by a suitable concentrating procedure." [Such procedure may include distillation and/orextraction, and
it is illustrated inthe drawing as extraction step 11. t This step may comprise extraction of the reformate'product, or a fraction thereof obtainedby distillation, with a suitable solvent selective for the aromatic component, for example, with diethylene glycol containing a minor amount of water. The aromatic :extract .is..recovered from the solvent by distillation andv is normally water washed to remove traces of solvent. .Thisresults .in an aromatic fraction which is relatively wettdue to the :fact that the solubilityof water in..aromatic:hydrocarbons is substantial.
The. wetaromatic fraction obtained. from stepll must be subjected .to a drying step 12 beforetreatment-with clay in accordance with the present invention. -Any known or suitable dryingprccedure capable of reducing the water content below 200 p. p. m. maybe used for this purpose. A particularly suitable procedure'forco'min the distillate.
.er than No. 1.
mercial practice involves distillation of a minor portion of the aromatic fraction, whereby the water concentrates For example, if of the wet aromatic fraction is distilled, most of the water will pass overhead with the aromatic distillate and, after condensaf tion, will separate therefrom as a water layer. The wet aromatic layer may, if desired, be recycled back to the drying step. This procedure will yield an aromatic fraction of low water content suitable for treatment in the next step of the operation.
The next step, illustrated in the drawing by numeral 13, is the treating step in which the dried aromatic stock in liquid form is brought into contact at elevated temperature with adsorptive clay having a combined water content of 4i5-7.5%. For this purpose the clay can be prepared by roasting conventional commercial clay of higher moisture content at a temperature of, for example, about 1000 F. until the combined water content is reduced to within the desired range of 4.5-7.5% and preferably to 5.86.5%. The specified range of cornbined water content of the clay is critical for obtaining the desired improvement according to the invention. The temperature of treatment in step 13 should be above 275 F., preferably 300-375 F., with the prestually the clay will lose its activity, probably due to accumulation of polymers therein, and will have to be replaced by fresh clay or regenerated before further use. The high yield of product obtained according to the invention, however, will minimize the cost of replacement or regeneration of the clay.
The efiluent from the clay treating step 13 generally has an acid wash color substantially improved over that of the aromatic charge but contains some polymeric materials which preferably should be removed to improve acid wash color still further. This may be done 'by means of distillation step 14. In this step the treated aromatic is distilled overhead leaving the undesirable polymeric material as residuum. The yield of distillate meeting nitration grade specifications will be in excess of 2000 bbls. per ton of the clay used in step 13 and yields of the order of 30003500 bbls./ton can readily be obtained. As a general rule, the acid wash color of the distillate product will remain more or less constant at a satisfactorily low value until a certain yield in excess of 2000 bbls./ton is reached, after which the acid wash color will sharply increase to an unsatisfactorily high value. When this occurs, the clay should be replaced with fresh or regenerated clay of the proper water content.
The following examples, in which precentages are by weight unless otherwise specified, illustrate the improvement obtained according to the invention and show the importance of water content.
Example I A commercial clay, designated as 30/60 mesh Attapulgus Grade AA and which had been roasted to a free water content of 0.4% and a combined water content of 10.1%, was used for treating a stock .of petroleum benzene obtained from a reforming operation. The charge stock contained about 98% benzene and met nitration grade specifications except for the acid wash color which was 4. Nitration grade, specifications require an acid wash color not darker than No. 2 color standard and it is desirable that such color be not great- The charge was first dried by filtration through silica gel and then was filtered under pressure and at a temperature of about 300 F. through a'column packed with the clay. A space rate of 5.8 liquid volumes per bulk volume of clay per hour was maintained. Samples of the filtrate were collected and tested for acid wash color both before and after distillation. The effluent up to a yield of about 1000 bbls./ton had acid wash colors before and after distillation of about 1 and 0+, respectively. Thereafter, the acid wash color increased rapidly so that the filtrate, even after distillation, no longer met the acid wash color specification for nitration grade benzene when the yield exceeded about 1500 bbls./ton.
Example II Another batch of the benzene specified in Example I and dried by means of silica gel was treated in essentially the same manner with the same type of clay as in that example, but in this case the clay had been roasted until it contained 6.1% combined water and no free water. At a yield of 2000 bbls./ton the acidwash colors for the filtrate before and after distillation were 1 and 0+, respectively; and at a yield of 3000 bbls./ton the colors had increased only slightly to about 1+ and l,
respectively. Nitration grade specifications were met until a yield of about 3500 bbls./ton was reached, at which time the colors for both the undistilled and distilled product increased sharply to about 3.
Example 111 Another run was made as in the preceding example, but in this case the clay had been roasted to a combined water content of 4.0% and no free water. It was found that the yield of nitration grade product was zero. Even the initial filtrate after distillation had about the same acid wash color as the charge benzene. This illustrates the importance of maintaining the combined water content of the clay within the specified range.
Example IV The aromatic stock in this case was another commercial benzene prepared by reforming a petroleum naphtha, extracting the reformate with diethylene glycol and water washing. The stock contained of the order of 800 p. p. m. ofwater and had an acid wash color of 12. One portion of the stock was clay treated without drying, while another portion was first subjected to a drying step by distilling 5 vol. overhead so that its water content was reduced to 162 p. p. to. Each portion was filtered as a liquid at 300 F. and at a space rate of 1.0 through 30/60 AA Attapulgus clay which had been roasted to a combined water content of 6.0% and no free water. .The yield of distilled filtrate having acid wash color not darker than No. l was only 980 bbls./ ton of clay with the undried stock, whereas the stock dried to 162 p. p. m. showed a distilled filtrate yield in excess of 3000 bbls./ton. This illustrates the importance of having the water content of the aromatic charge below 200 p. p. m.
Example V A blend composed of, by volume, 47.5% reformer benzene having an acid wash color of 4, 47.5% reformer toluene having an acid wash color of 5+ and 5% n-butane was used as the aromatic charge stock. its water content was less than p. p. m. The clay used was 30/60 AA Attapulgus having no free water and a combined water content of 6.0%. Treatment of the charge stock was effected at a temperature of 300 15., a pressure of 300 p. s. i. g. and a space rate varying from 3.4 to 5.8. The eflluent from the clay treater was stripped of butane and distilled to obtain a polymerfree mixture of benzene and toluene. At a yield of 2200 bbls./ton the mixed benzene and toluene product had an acid wash color less than 1. Thereafter, the
operation was continued by filtering toluene alone through the clay. The acid wash color of the distilled filtrate remained less than 1 until a total aromatic yield of 2800 bbls./ton was exceeded, whereupon the color increased sharply to above 3.
While the foregoing examples are specific to the treatment of stocks containing C6-C7 aromatic hydrocarbon, it will be understood that the invention is applicable to the preparation of nitration grade products from higher boiling aromatics.
We claim:
1. In a process of making nitration grade aromatic hydrocarbon which comprises reforming a petroleum naphtha, extracting the reformate with a water soluble solvent to yield an aromatic rich hydrocarbon fraction containing a minor amount of said solvent, and water washing said aromatic rich fraction to remove said solvent, the steps whichcomprise removing water from the water washed aromatic fraction to yield an aromatic stock having a water content less than 200 p. p. m., treating said stock in liquid phase at a temperature between 275 F. and its critical temperature with adsorptive clay having a combined water content between 4.5% and 7.5% by weight, and recovering from the treated material nitration grade aromatic'product in a yield exceeding 2000 barrels per ton of clay.
2. Process according to claim 1 wherein said aromatic stock is Cs-C7 aromatic hydrocarbon and the combined water content of the clay is 5.86.5% by weight.
3. In a process of making nitration grade aromatic hydrocarbon which comprises reforming a petroleum naphtha and extracting the reformate in the presence 1 of water, the steps which comprise obtaining from said reformate an aromatic rich hydrocarbon fraction having a water content less than 200 p. p. m., treating said frac tion in liquid phase at a temperature between 275 F. and its critical temperature with adsorptive clay having a combined water content between 4.5 and 7.5 by weight, and recovering from the treated material nitration grade aromatic product in a yield exceeding 2000 barrels per ton of clay.
4. Process according to claim 3 wherein said aromatic rich hydrocarbon fraction is C6-C7 aromatic hydrocarbon and the combined water content of the clay is 5.8- 6.5% by weight.
References Cited in the file of this patent UNITED STATES PATENTS 2,232,761 Balthis Feb. 25, 1941 2,366,570 Souders et al. Jan. 2, 1945 2,400,355 Jones et a1. May 14, 1946 2,400,802 Arnold May 21, 1946 2,664,202 Bartleson Dec. 29, 1953 2,713,552 Lien et a1 July 19, 1955 OTHER REFERENCES The Science of Petroleum, Oxford University Press (1938), vol. III, edited by Dunstan et al., pp. 1680 and 1

Claims (1)

1. IN A PROCESS OF MAKING NITRATION GRADE AROMATIC HYDROCARBON WHICH COMPRISES REFORMING A PETROLEUM NAPHTHA, EXTRACTING THE REFORMATE WITH A WATER SOLUBLE SOLVENT TO YIELD AN AROMATIC RICH HYDROCARBON FRACTION CONTAINING A MINOR AMOUNT OF SAID SOLVENT, AND WATER WASHING SAID AROMATIC RICH FRACTION TO REMOVE SAID SOLVENT, THE STEPS WHICH COMPRISE REMOVING WATER FROM THE WATER WASHED AROMATIC FRACTION TO YIELD AN AROMATIC STOCK HAVING A WATER CONTENT LESS THAN 200 P. P. M., TREATING SAID STOCK IN LIQUID PHASE AT A TEMPERATURE BETWEEN 275* F. AND ITS CRITICAL TEMPERATURE WITH ADSORPTIVE CLAY HAVING A COMBINED WATER CONTENT BETWEEN 4.5% AND 7.5% BY WEIGHT, AND RECOVERING FROM THE TREATED MATERIAL NITRATION GRADE AROMATIC PRODUCT IN A YIELD EXCEEDING 2000 BARRELS PER TON OF CLAY.
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Cited By (3)

* Cited by examiner, † Cited by third party
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US2888498A (en) * 1956-02-29 1959-05-26 Phillips Petroleum Co Production of colorless emulsion-polymerized polymers
US4024026A (en) * 1976-08-26 1977-05-17 Uop Inc. Temperature control of integrated fractionation and claytreating of hydrocarbons
US4053367A (en) * 1976-08-26 1977-10-11 Uop Inc. Temperature control of integrated fractionation and claytreating of hydrocarbons

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US2232761A (en) * 1938-09-21 1941-02-25 Du Pont Process for the treatment of petroleum distillates
US2366570A (en) * 1942-05-26 1945-01-02 Shell Dev Treatment of hydrocarbons
US2400355A (en) * 1942-10-14 1946-05-14 Standard Oil Dev Co Production of aromatics
US2400802A (en) * 1941-03-08 1946-05-21 Texas Co Separation of aromatic hydrocarbons from hydrocarbon mixtures
US2664202A (en) * 1949-12-22 1953-12-29 Standard Oil Co Lubricant and method of making same
US2713552A (en) * 1951-10-17 1955-07-19 Standard Oil Co Extraction of aromatics from naphthas

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US2400802A (en) * 1941-03-08 1946-05-21 Texas Co Separation of aromatic hydrocarbons from hydrocarbon mixtures
US2366570A (en) * 1942-05-26 1945-01-02 Shell Dev Treatment of hydrocarbons
US2400355A (en) * 1942-10-14 1946-05-14 Standard Oil Dev Co Production of aromatics
US2664202A (en) * 1949-12-22 1953-12-29 Standard Oil Co Lubricant and method of making same
US2713552A (en) * 1951-10-17 1955-07-19 Standard Oil Co Extraction of aromatics from naphthas

Cited By (3)

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US2888498A (en) * 1956-02-29 1959-05-26 Phillips Petroleum Co Production of colorless emulsion-polymerized polymers
US4024026A (en) * 1976-08-26 1977-05-17 Uop Inc. Temperature control of integrated fractionation and claytreating of hydrocarbons
US4053367A (en) * 1976-08-26 1977-10-11 Uop Inc. Temperature control of integrated fractionation and claytreating of hydrocarbons

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